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    <h1>Core Concepts</h1>
    <div class="sub-nav-sticky">
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            <div style="height:35px">
                <a href="/{{version}}/documentation/streams/">Introduction</a>
                <a href="/{{version}}/documentation/streams/quickstart">Run Demo App</a>
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                <a class="active-menu-item" href="/{{version}}/documentation/streams/core-concepts">Concepts</a>
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    <p>
        Kafka Streams is a client library for processing and analyzing data stored in Kafka.
        It builds upon important stream processing concepts such as properly distinguishing between event time and processing time, windowing support, and simple yet efficient management and real-time querying of application state.
    </p>
    <p>
        Kafka Streams has a <b>low barrier to entry</b>: You can quickly write and run a small-scale proof-of-concept on a single machine; and you only need to run additional instances of your application on multiple machines to scale up to high-volume production workloads.
        Kafka Streams transparently handles the load balancing of multiple instances of the same application by leveraging Kafka's parallelism model.
    </p>
    <p>
        Some highlights of Kafka Streams:
    </p>

    <ul>
        <li>Designed as a <b>simple and lightweight client library</b>, which can be easily embedded in any Java application and integrated with any existing packaging, deployment and operational tools that users have for their streaming applications.</li>
        <li>Has <b>no external dependencies on systems other than Apache Kafka itself</b> as the internal messaging layer; notably, it uses Kafka's partitioning model to horizontally scale processing while maintaining strong ordering guarantees.</li>
        <li>Supports <b>fault-tolerant local state</b>, which enables very fast and efficient stateful operations like windowed joins and aggregations.</li>
        <li>Supports <b>exactly-once</b> processing semantics to guarantee that each record will be processed once and only once even when there is a failure on either Streams clients or Kafka brokers in the middle of processing.</li>
        <li>Employs <b>one-record-at-a-time processing</b> to achieve millisecond processing latency, and supports <b>event-time based windowing operations</b> with out-of-order arrival of records.</li>
        <li>Offers necessary stream processing primitives, along with a <b>high-level Streams DSL</b> and a <b>low-level Processor API</b>.</li>

    </ul>

    <p>
        We first summarize the key concepts of Kafka Streams.
    </p>

    <h3 class="anchor-heading"><a id="streams_topology" class="anchor-link"></a><a href="#streams_topology">Stream Processing Topology</a></h3>

    <ul>
        <li>A <b>stream</b> is the most important abstraction provided by Kafka Streams: it represents an unbounded, continuously updating data set. A stream is an ordered, replayable, and fault-tolerant sequence of immutable data records, where a <b>data record</b> is defined as a key-value pair.</li>
        <li>A <b>stream processing application</b> is any program that makes use of the Kafka Streams library. It defines its computational logic through one or more <b>processor topologies</b>, where a processor topology is a graph of stream processors (nodes) that are connected by streams (edges).</li>
        <li>A <a id="defining-a-stream-processor" href="/{{version}}/documentation/streams/developer-guide/processor-api#defining-a-stream-processor"><b>stream processor</b></a> is a node in the processor topology; it represents a processing step to transform data in streams by receiving one input record at a time from its upstream processors in the topology, applying its operation to it, and may subsequently produce one or more output records to its downstream processors. </li>
    </ul>

    There are two special processors in the topology:

    <ul>
        <li><b>Source Processor</b>: A source processor is a special type of stream processor that does not have any upstream processors. It produces an input stream to its topology from one or multiple Kafka topics by consuming records from these topics and forwarding them to its down-stream processors.</li>
        <li><b>Sink Processor</b>: A sink processor is a special type of stream processor that does not have down-stream processors. It sends any received records from its up-stream processors to a specified Kafka topic.</li>
    </ul>

    Note that in normal processor nodes other remote systems can also be accessed while processing the current record. Therefore the processed results can either be streamed back into Kafka or written to an external system.

    <img class="centered" src="/{{version}}/images/streams-architecture-topology.jpg" style="width:400px">

    <p>
        Kafka Streams offers two ways to define the stream processing topology: the <a href="/{{version}}/documentation/streams/developer-guide/dsl-api.html"><b>Kafka Streams DSL</b></a> provides
        the most common data transformation operations such as <code>map</code>, <code>filter</code>, <code>join</code> and <code>aggregations</code> out of the box; the lower-level <a href="/{{version}}/documentation/streams/developer-guide/processor-api.html"><b>Processor API</b></a> allows
        developers define and connect custom processors as well as to interact with <a href="#streams_state">state stores</a>.
    </p>

    <p>
        A processor topology is merely a logical abstraction for your stream processing code.
        At runtime, the logical topology is instantiated and replicated inside the application for parallel processing (see <a href="/{{version}}/documentation/streams/architecture#streams_architecture_tasks"><b>Stream Partitions and Tasks</b></a> for details).
    </p>

    <h3 class="anchor-heading"><a id="streams_time" class="anchor-link"></a><a href="#streams_time">Time</a></h3>

    <p>
        A critical aspect in stream processing is the notion of <b>time</b>, and how it is modeled and integrated.
        For example, some operations such as <b>windowing</b> are defined based on time boundaries.
    </p>
    <p>
        Common notions of time in streams are:
    </p>

    <ul>
        <li><b>Event time</b> - The point in time when an event or data record occurred, i.e. was originally created "at the source". <b>Example:</b> If the event is a geo-location change reported by a GPS sensor in a car, then the associated event-time would be the time when the GPS sensor captured the location change.</li>
        <li><b>Processing time</b> - The point in time when the event or data record happens to be processed by the stream processing application, i.e. when the record is being consumed. The processing time may be milliseconds, hours, or days etc. later than the original event time. <b>Example:</b> Imagine an analytics application that reads and processes the geo-location data reported from car sensors to present it to a fleet management dashboard. Here, processing-time in the analytics application might be milliseconds or seconds (e.g. for real-time pipelines based on Apache Kafka and Kafka Streams) or hours (e.g. for batch pipelines based on Apache Hadoop or Apache Spark) after event-time.</li>
        <li><b>Ingestion time</b> - The point in time when an event or data record is stored in a topic partition by a Kafka broker. The difference to event time is that this ingestion timestamp is generated when the record is appended to the target topic by the Kafka broker, not when the record is created "at the source". The difference to processing time is that processing time is when the stream processing application processes the record. <b>For example,</b> if a record is never processed, there is no notion of processing time for it, but it still has an ingestion time.</li>
    </ul>
    <p>
        The choice between event-time and ingestion-time is actually done through the configuration of Kafka (not Kafka Streams): From Kafka 0.10.x onwards, timestamps are automatically embedded into Kafka messages. Depending on Kafka's configuration these timestamps represent event-time or ingestion-time. The respective Kafka configuration setting can be specified on the broker level or per topic. The default timestamp extractor in Kafka Streams will retrieve these embedded timestamps as-is. Hence, the effective time semantics of your application depend on the effective Kafka configuration for these embedded timestamps.
    </p>
    <p>
        Kafka Streams assigns a <b>timestamp</b> to every data record via the <code>TimestampExtractor</code> interface.
        These per-record timestamps describe the progress of a stream with regards to time and are leveraged by	time-dependent operations such as window operations.
        As a result, this time will only advance when a new record arrives at the processor.
        We call this data-driven time the <b>stream time</b> of the application to differentiate with the <b>wall-clock time</b> when this application is actually executing.
        Concrete implementations of the <code>TimestampExtractor</code> interface will then provide different semantics to the stream time definition.
        For example retrieving or computing timestamps based on the actual contents of data records such as an embedded timestamp field to provide event time semantics,
        and returning the current wall-clock time thereby yield processing time semantics to stream time.
        Developers can thus enforce different notions of time depending on their business needs.
    </p>

    <p>
        Finally, whenever a Kafka Streams application writes records to Kafka, then it will also assign timestamps to these new records. The way the timestamps are assigned depends on the context:
    </p>

    <ul>
        <li> When new output records are generated via processing some input record, for example, <code>context.forward()</code> triggered in the <code>process()</code> function call, output record timestamps are inherited from input record timestamps directly.</li>
        <li> When new output records are generated via periodic functions such as <code>Punctuator#punctuate()</code>, the output record timestamp is defined as the current internal time (obtained through <code>context.timestamp()</code>) of the stream task.</li>
        <li> For aggregations, the timestamp of a result update record will be the maximum timestamp of all input records contributing to the result.</li>
    </ul>

    <p>
        You can change the default behavior in the Processor API by assigning
        timestamps to output records explicitly when calling <code>#forward()</code>.
    </p>

    <p>
        For aggregations and joins, timestamps are computed by using the
        following rules. 
    </p>

    <p>
        <ul>
            <li>For joins (stream-stream, table-table) that have left and right
                input records, the timestamp of the output record is assigned
                <code>max(left.ts, right.ts)</code>.</li>
            <li>For stream-table joins, the output record is assigned the timestamp
                from the stream record.</li>
            <li>For aggregations, Kafka Streams also computes the <code>max</code>
                timestamp over all records, per key, either globally (for non-windowed)
                or per-window.</li>
            <li>For stateless operations, the input record timestamp is passed through.
                For <code>flatMap</code> and siblings that emit multiple records, all
                output records inherit the timestamp from the corresponding input record.</li>
        </ul>
    </p>
    
    <p>

    </p>

    <h3 class="anchor-heading"><a id="streams_concepts_duality" class="anchor-link"></a><a href="#streams_concepts_duality">Duality of Streams and Tables</a></h3>
    <p>
        When implementing stream processing use cases in practice, you typically need both <strong>streams</strong> and also <strong>databases</strong>.
        An example use case that is very common in practice is an e-commerce application that enriches an incoming <em>stream</em> of customer
        transactions with the latest customer information from a <em>database table</em>. In other words, streams are everywhere, but databases are everywhere, too.
    </p>

    <p>
      Any stream processing technology must therefore provide <strong>first-class support for streams and tables</strong>.
      Kafka's Streams API provides such functionality through its core abstractions for 
      <a id="streams_concepts_kstream" href="/{{version}}/documentation/streams/developer-guide/dsl-api#streams_concepts_kstream">streams</a>
      and <a id="streams_concepts_ktable" href="/{{version}}/documentation/streams/developer-guide/dsl-api#streams_concepts_ktable">tables</a>,
      which we will talk about in a minute. Now, an interesting observation is that there is actually a <strong>close relationship between streams and tables</strong>,
      the so-called stream-table duality. And Kafka exploits this duality in many ways: for example, to make your applications
      <a id="streams-developer-guide-execution-scaling" href="/{{version}}/documentation/streams/developer-guide/running-app#elastic-scaling-of-your-application">elastic</a>,
      to support <a id="streams_architecture_recovery" href="/{{version}}/documentation/streams/architecture#streams_architecture_recovery">fault-tolerant stateful processing</a>,
      or to run <a id="streams-developer-guide-interactive-queries" href="/{{version}}/documentation/streams/developer-guide/interactive-queries#interactive-queries">interactive queries</a>
      against your application's latest processing results. And, beyond its internal usage, the Kafka Streams API
      also allows developers to exploit this duality in their own applications.
  </p>

  <p>
      Before we discuss concepts such as <a id="streams-developer-guide-dsl-aggregating" href="/{{version}}/documentation/streams/developer-guide/dsl-api#aggregating">aggregations</a>
      in Kafka Streams, we must first introduce <strong>tables</strong> in more detail, and talk about the aforementioned stream-table duality.
      Essentially, this duality means that a stream can be viewed as a table, and a table can be viewed as a stream. Kafka's log compaction feature, for example, exploits this duality.
    </p>

    <p>
        A simple form of a table is a collection of key-value pairs, also called a map or associative array. Such a table may look as follows:
    </p>
    <img class="centered" src="/{{version}}/images/streams-table-duality-01.png">

    The <b>stream-table duality</b> describes the close relationship between
    streams and tables.
    <ul>
        <li><b>Stream as Table</b>: A stream can be considered a changelog of a
            table, where each data record in the stream captures a state change
            of the table. A stream is thus a table in disguise, and it can be
            easily turned into a "real" table by replaying the changelog from
            beginning to end to reconstruct the table. Similarly, in a more
            general analogy, aggregating data records in a stream - such as
            computing the total number of pageviews by user from a stream of
            pageview events - will return a table (here with the key and the
            value being the user and its corresponding pageview count,
            respectively).</li>
        <li><b>Table as Stream</b>: A table can be considered a snapshot, at a
            point in time, of the latest value for each key in a stream (a
            stream's data records are key-value pairs). A table is thus a
            stream in disguise, and it can be easily turned into a "real"
            stream by iterating over each key-value entry in the table.</li>
    </ul>

    <p>
        Let's illustrate this with an example. Imagine a table that tracks the
        total number of pageviews by user (first column of diagram below). Over
        time, whenever a new pageview event is processed, the state of the
        table is updated accordingly. Here, the state changes between different
        points in time - and different revisions of the table - can be
        represented as a changelog stream (second column).
    </p>
    <img class="centered" src="/{{version}}/images/streams-table-duality-02.png" style="width:300px">

    <p>
        Interestingly, because of the stream-table duality, the same stream
        can be used to reconstruct the original table (third column):
    </p>
    <img class="centered" src="/{{version}}/images/streams-table-duality-03.png" style="width:600px">

    <p>
        The same mechanism is used, for example, to replicate databases via
        change data capture (CDC) and, within Kafka Streams, to replicate its
        so-called state stores across machines for fault-tolerance. The stream-table
        duality is such an important concept that Kafka Streams models it explicitly
        via the <a href="#streams_kstream_ktable">KStream, KTable, and GlobalKTable</a>
        interfaces.
    </p>

    <h3><a id="streams_concepts_aggregations" href="#streams_concepts_aggregations">Aggregations</a></h3>
    <p>
        An <strong>aggregation</strong> operation takes one input stream or table, and yields a new table by combining multiple input records into a single output record. Examples of aggregations are computing counts or sum.
    </p>

    <p>
        In the <code>Kafka Streams DSL</code>, an input stream of an <code>aggregation</code> can be a KStream or a KTable, but the output stream will always be a KTable. This allows Kafka Streams to update an aggregate value upon the out-of-order arrival of further records after the value was produced and emitted. When such out-of-order arrival happens, the aggregating KStream or KTable emits a new aggregate value. Because the output is a KTable, the new value is considered to overwrite the old value with the same key in subsequent processing steps.
    </p>

    <h3> <a id="streams_concepts_windowing" href="#streams_concepts_windowing">Windowing</a></h3>
    <p>
        Windowing lets you control how to <em>group records that have the same key</em> for stateful operations such as <code>aggregations</code> or <code>joins</code> into so-called <em>windows</em>. Windows are tracked per record key.
    </p>
    <p>
        <code>Windowing operations</code> are available in the <code>Kafka Streams DSL</code>. When working with windows, you can specify a <strong>grace period</strong> for the window. This grace period controls how long Kafka Streams will wait for <strong>out-of-order</strong> data records for a given window. If a record arrives after the grace period of a window has passed, the record is discarded and will not be processed in that window. Specifically, a record is discarded if its timestamp dictates it belongs to a window, but the current stream time is greater than the end of the window plus the grace period.
    </p>
    <p>
        Out-of-order records are always possible in the real world and should be properly accounted for in your applications. It depends on the effective <code>time semantics </code> how out-of-order records are handled. In the case of processing-time, the semantics are &quot;when the record is being processed&quot;, which means that the notion of out-of-order records is not applicable as, by definition, no record can be out-of-order. Hence, out-of-order records can only be considered as such for event-time. In both cases, Kafka Streams is able to properly handle out-of-order records.
    </p>

    <h3><a id="streams_state" href="#streams_state">States</a></h3>

    <p>
        Some stream processing applications don't require state, which means the processing of a message is independent from
        the processing of all other messages.
        However, being able to maintain state opens up many possibilities for sophisticated stream processing applications: you
        can join input streams, or group and aggregate data records. Many such stateful operators are provided by the <a href="/{{version}}/documentation/streams/developer-guide/dsl-api.html"><b>Kafka Streams DSL</b></a>.
    </p>
    <p>
        Kafka Streams provides so-called <b>state stores</b>, which can be used by stream processing applications to store and query data.
        This is an important capability when implementing stateful operations.
        Every task in Kafka Streams embeds one or more state stores that can be accessed via APIs to store and query data required for processing.
        These state stores can either be a persistent key-value store, an in-memory hashmap, or another convenient data structure.
        Kafka Streams offers fault-tolerance and automatic recovery for local state stores.
    </p>
    <p>
        Kafka Streams allows direct read-only queries of the state stores by methods, threads, processes or applications external to the stream processing application that created the state stores. This is provided through a feature called <b>Interactive Queries</b>. All stores are named and Interactive Queries exposes only the read operations of the underlying implementation.
    </p>
    <br>

    <h2 class="anchor-heading"><a id="streams_processing_guarantee" class="anchor-link"></a><a href="#streams_processing_guarantee">Processing Guarantees</a></h2>

    <p>
        In stream processing, one of the most frequently asked question is "does my stream processing system guarantee that each record is processed once and only once, even if some failures are encountered in the middle of processing?"
        Failing to guarantee exactly-once stream processing is a deal-breaker for many applications that cannot tolerate any data-loss or data duplicates, and in that case a batch-oriented framework is usually used in addition
        to the stream processing pipeline, known as the <a href="http://lambda-architecture.net/">Lambda Architecture</a>.
        Prior to 0.11.0.0, Kafka only provides at-least-once delivery guarantees and hence any stream processing systems that leverage it as the backend storage could not guarantee end-to-end exactly-once semantics.
        In fact, even for those stream processing systems that claim to support exactly-once processing, as long as they are reading from / writing to Kafka as the source / sink, their applications cannot actually guarantee that
        no duplicates will be generated throughout the pipeline.<br />

        Since the 0.11.0.0 release, Kafka has added support to allow its producers to send messages to different topic partitions in a <a href="https://kafka.apache.org/documentation/#semantics">transactional and idempotent manner</a>,
        and Kafka Streams has hence added the end-to-end exactly-once processing semantics by leveraging these features.
        More specifically, it guarantees that for any record read from the source Kafka topics, its processing results will be reflected exactly once in the output Kafka topic as well as in the state stores for stateful operations.
        Note the key difference between Kafka Streams end-to-end exactly-once guarantee with other stream processing frameworks' claimed guarantees is that Kafka Streams tightly integrates with the underlying Kafka storage system and ensure that
        commits on the input topic offsets, updates on the state stores, and writes to the output topics will be completed atomically instead of treating Kafka as an external system that may have side-effects.
        For more information on how this is done inside Kafka Streams, see <a href="https://cwiki.apache.org/confluence/display/KAFKA/KIP-129%3A+Streams+Exactly-Once+Semantics">KIP-129</a>.<br />

        As of the 2.6.0 release, Kafka Streams supports an improved implementation of exactly-once processing, named "exactly-once v2",
        which requires broker version 2.5.0 or newer.
        This implementation is more efficient, because it reduces client and broker resource utilization, like client threads and used network connections, 
        and it enables higher throughput and improved scalability.
        As of the 3.0.0 release, the first version of exactly-once has been deprecated. Users are encouraged to use exactly-once v2 for
        exactly-once processing from now on, and prepare by upgrading their brokers if necessary.
        For more information on how this is done inside the brokers and Kafka Streams, see 
        <a href="https://cwiki.apache.org/confluence/display/KAFKA/KIP-447%3A+Producer+scalability+for+exactly+once+semantics">KIP-447</a>.<br />

        To enable exactly-once semantics when running Kafka Streams applications,
        set the <code>processing.guarantee</code> config value (default value is <b>at_least_once</b>)
        to <b>StreamsConfig.EXACTLY_ONCE_V2</b> (requires brokers version 2.5 or newer).
        For more information, see the <a href="/{{version}}/documentation/streams/developer-guide/config-streams.html">Kafka Streams Configs</a> section.
    </p>

    <h3 class="anchor-heading"><a id="streams_out_of_ordering" class="anchor-link"></a><a href="#streams_out_of_ordering">Out-of-Order Handling</a></h3>

    <p>
        Besides the guarantee that each record will be processed exactly-once, another issue that many stream processing applications will face is how to
        handle <a href="https://dl.acm.org/citation.cfm?id=3242155">out-of-order data</a> that may impact their business logic. In Kafka Streams, there are two causes that could potentially
        result in out-of-order data arrivals with respect to their timestamps:
    </p>

    <ul>
        <li> Within a topic-partition, a record's timestamp may not be monotonically increasing along with their offsets. Since Kafka Streams will always try to process records within a topic-partition to follow the offset order,
            it can cause records with larger timestamps (but smaller offsets) to be processed earlier than records with smaller timestamps (but larger offsets) in the same topic-partition.
        </li>
        <li> Within a <a href="/{{version}}/documentation/streams/architecture#streams_architecture_tasks">stream task</a> that may be processing multiple topic-partitions, if users configure the application to not wait for all partitions to contain some buffered data and
             pick from the partition with the smallest timestamp to process the next record, then later on when some records are fetched for other topic-partitions, their timestamps may be smaller than those processed records fetched from another topic-partition.
        </li>
    </ul>

    <p>
        For stateless operations, out-of-order data will not impact processing logic since only one record is considered at a time, without looking into the history of past processed records;
        for stateful operations such as aggregations and joins, however, out-of-order data could cause the processing logic to be incorrect. If users want to handle such out-of-order data, generally they need to allow their applications
        to wait for longer time while bookkeeping their states during the wait time, i.e. making trade-off decisions between latency, cost, and correctness.
        In Kafka Streams specifically, users can configure their window operators for windowed aggregations to achieve such trade-offs (details can be found in <a href="/{{version}}/documentation/streams/developer-guide"><b>Developer Guide</b></a>).
        As for Joins, users may use <a href="/{{version}}/documentation/streams/developer-guide/dsl-api.html#versioned-state-stores">versioned state stores</a> to address concerns with out-of-order data, but out-of-order data will not be handled by default:
    </p>

    <ul>
        <li> For Stream-Stream joins, all three types (inner, outer, left) handle out-of-order records correctly.</li>
        <li> For Stream-Table joins, if not using versioned stores, then out-of-order records are not handled (i.e., Streams applications don't check for out-of-order records and just process all records in offset order),
            and hence it may produce unpredictable results. With versioned stores, stream-side out-of-order data will be properly handled by performing a timestamp-based lookup in the table. Table-side out-of-order data is still not handled.</li>
        <li> For Table-Table joins, if not using versioned stores, then out-of-order records are not handled (i.e., Streams applications don't check for out-of-order records and just process all records in offset order).
            However, the join result is a changelog stream and hence will be eventually consistent. With versioned stores, table-table join semantics change from offset-based semantics to
            <a href="/{{version}}/documentation/streams/developer-guide/dsl-api.html#versioned-state-stores">timestamp-based semantics</a> and out-of-order records are handled accordingly.</li>
    </ul>

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